The first body of work to be explored in this project focussed on two electrode materials, molybdenum disulfide and pentlandite, which are both electrocatalysts for the hydrogen evolution reaction, the process that occurs at the cathode of electrolysers, producing hydrogen fuel from water. “Scanning probe” techniques were used to reveal the “active sites” of both materials, which allowed us to optimize their performance for water splitting (hydrogen fuel generation). These works were disseminated via publication:
(1) Bentley, C. L., et al., "Electrochemical Maps and Movies of the Hydrogen Evolution Reaction on Natural Crystals of Molybdenite (MoS2): Basal vs. Edge Plane Activity", Chemical Science 2017, 8 (9), 6583-6593.
(2) Bentley, C. L., et al., "Local Surface Structure and Composition Control the Hydrogen Evolution Reaction on Iron Nickel Sulfides", Angewandte Chemie International Edition 2018, 57 (15), 4093-4097.
The latter piece of work was also featured in Science Daily:
“Robust and inexpensive catalysts for hydrogen production”, April 10 2018,
https://www.sciencedaily.com/releases/2018/04/180410103512.htm(si apre in una nuova finestra) After completing these works, significant focus was given to improving the “scanning probe” techniques, specifically the spatial-resolution, which allowed us to interrogate more minute structural features of electrodes, further facilitating rational electrode design. Again, these works were disseminated via publication:
(3) Kang, M., et al., "Simultaneous Topography and Reaction Flux Mapping at and around Electrocatalytic Nanoparticles", ACS Nano 2017, 11 (9), 9525-9535.
(4) Bentley, C. L., et al., "Nanoscale Structure Dynamics within Electrocatalytic Materials", Journal of the American Chemical Society 2017, 139 (46), 16813-16821.
The latter study produced a lot of interest, with presentations given at a number of internationally-leading conferences, including Electrochem 2017 (Birmingham, U.K.) Gordon Research Conference on Electrochemistry (Ventura, U.S.A.) and 69th Annual Meeting of the International Society of Electrochemistry (Bologna, Italy).
After completing these works, we further developed some of the technical aspects of the “scanning probe”, specifically, how to implement these techniques for renewable energy materials (e.g. electrocatalyst) research. Again, these works were disseminated via publication:
(5) Bentley, C. L., et al., "Stability and Placement of Ag/AgCl Quasi-Reference Counter Electrodes in Confined Electrochemical Cells", Analytical Chemistry 2018, 90 (12), 7700-7707.
(6) Bentley, C. L., et al., "Nanoscale electrochemical movies and synchronous topographical mapping of electrocatalytic materials", Faraday Discussions 2018, 210, 365-379.
Over the project period, two review articles addressing various aspects of the use of the “scanning probe”, as well as implementation of ionic liquids as electrolytes were also published:
(7) Bentley, C. L., et al., "Scanning electrochemical cell microscopy: New perspectives on electrode processes in action", Current Opinion in Electrochemistry 2017, 6 (1), 23-30.
(8) Bentley, C. L., et al., "Voltammetric Perspectives on the Acidity Scale and H+/H2 Process in Ionic Liquid Media", Annual Review of Analytical Chemistry 2018, 11 (1), 397-419.
Finally, since finalizing the above publications, the optimized “scanning probe” techniques have been used to investigate a range of phenomena in electrocatalysis and beyond (e.g. ionic liquid electrolytes).